Project description:Cellular reprogramming of cardiac fibroblasts to cardiomyocytes following myocardial infarction (MI) is an attractive strategy to redirect the fibrotic response of the non-regenerative adult heart to a more functional myocardium. Current reprogramming strategies are inefficient or require an excess of factors in adult and human cells due to staunch epigenetic barriers. Recently, we identified the epigenetic factor PHF7 as a potent activating factor of in vitro adult fibroblast reprogramming through modification of chromatin accessibility at cardiac super-enhancers. Here, we report the ability of PHF7 to activate adult fibroblast reprogramming alongside minimal co-factors in vitro, and the efficacy of these cocktails in vivo following MI in mice. Further, delivery of PHF7 as a single factor to the mouse heart following MI induced reprogramming and improved cardiac function. Deployment of single nuclear multi-omics revealed that PHF7 induced fundamental changes in chromatin structure by enhancing accessibility at CTCF binding sites and inhibiting Jun/Fos transcription factor activity to permit reprogramming in the injured heart. Together, these data support the potential for epigenetic factors like PHF7 to achieve in vivo reprogramming in isolation when utilized in the appropriate niche.

Project description:Cellular reprogramming of cardiac fibroblasts to cardiomyocytes following myocardial infarction (MI) is an attractive strategy to redirect the fibrotic response of the non-regenerative adult heart to a more functional myocardium. Current reprogramming strategies are inefficient or require an excess of factors in adult and human cells due to staunch epigenetic barriers. Recently, we identified the epigenetic factor PHF7 as a potent activating factor of in vitro adult fibroblast reprogramming through modification of chromatin accessibility at cardiac super-enhancers. Here, we report the ability of PHF7 to activate adult fibroblast reprogramming alongside minimal co-factors in vitro, and the efficacy of these cocktails in vivo following MI in mice. Further, delivery of PHF7 as a single factor to the mouse heart following MI induced reprogramming and improved cardiac function. Deployment of single nuclear multi-omics revealed that PHF7 induced fundamental changes in chromatin structure by enhancing accessibility at CTCF binding sites and inhibiting Jun/Fos transcription factor activity to permit reprogramming in the injured heart. Together, these data support the potential for epigenetic factors like PHF7 to achieve in vivo reprogramming in isolation when utilized in the appropriate niche.

Project description:Direct cardiac reprogramming of fibroblasts to cardiomyocytes presents an attractive therapeutic strategy to restore cardiac function following injury. Cardiac reprogramming was initially achieved through the overexpression of the transcription factors Gata4, Mef2c, and Tbx5 (GMT), and later, Hand2 (GHMT) and Akt1 (AGHMT) were found to further enhance this process. Yet, staunch epigenetic barriers severely limit the ability of these cocktails to reprogram adult fibroblasts. We undertook a screen of mammalian gene regulatory factors to discover novel regulators of cardiac reprogramming in adult fibroblasts and identified the histone reader PHF7 as the most potent activating factor. Mechanistically, PHF7 localizes to cardiac super-enhancers in fibroblasts, and through cooperation with the SWI/SNF complex, increases chromatin accessibility and transcription factor binding at these sites. Importantly, PHF7 is the first epigenetic factor found to achieve efficient reprogramming in the absence of Gata4. Here, we highlight the underexplored necessity of cardiac epigenetic modifiers, such as PHF7, in harnessing chromatin remodeling complexes to overcome critical barriers to direct cardiac reprogramming.

Project description:Direct cardiac reprogramming of fibroblast to cardiomyocytes represents a potential means of restoring cardiac function following injury. However, aged and adult fibroblast are less efficient for reprogramming compared with neonatal fibroblast. In this study, through the joint analysis of RNAseq and ATACseq, we found that compared with Neo-iCM, cardiac related features were down-regulated with aging, while fibrosis and SASP related genes were significantly up-regulated with aging. Single-cell transcriptomics reveals a bifurcated trajectory of aged iCM reprogramming. Then, we screened 51 transcriptomic and epigenomic regulators of the barriers to aged-iCM reprogramming and found that Nuclear receptor subfamily 4 group A member 3 (Nr4a3), an pro-inflammatory transcription factor, induced cellular senescence to inhibit direct reprogramming during aging. Mechanistically, knockdown of Nr4a3 enhanced direct cardiac reprogramming by promoting cardiac gene programs and inhibiting fibrosis pathway and secretes SASP. In addition, knockdown of Nr4a3 promoted human reprogramming in primary ventricular human cardiac fibroblasts (HCFs) and improved heart function after MI.

Project description:Direct cardiac reprogramming of fibroblast to cardiomyocytes represents a potential means of restoring cardiac function following injury. However, aged and adult fibroblast are less efficient for reprogramming compared with neonatal fibroblast. In this study, through the joint analysis of RNAseq and ATACseq, we found that compared with Neo-iCM, cardiac related features were down-regulated with aging, while fibrosis and SASP related genes were significantly up-regulated with aging. Single-cell transcriptomics reveals a bifurcated trajectory of aged iCM reprogramming. Then, we screened 51 transcriptomic and epigenomic regulators of the barriers to aged-iCM reprogramming and found that Nuclear receptor subfamily 4 group A member 3 (Nr4a3), an pro-inflammatory transcription factor, induced cellular senescence to inhibit direct reprogramming during aging. Mechanistically, knockdown of Nr4a3 enhanced direct cardiac reprogramming by promoting cardiac gene programs and inhibiting fibrosis pathway and secretes SASP. In addition, knockdown of Nr4a3 promoted human reprogramming in primary ventricular human cardiac fibroblasts (HCFs) and improved heart function after MI.

Project description:Direct cardiac reprogramming of fibroblast to cardiomyocytes represents a potential means of restoring cardiac function following injury. However, aged and adult fibroblast are less efficient for reprogramming compared with neonatal fibroblast. In this study, through the joint analysis of RNAseq and ATACseq, we found that compared with Neo-iCM, cardiac related features were down-regulated with aging, while fibrosis and SASP related genes were significantly up-regulated with aging. Single-cell transcriptomics reveals a bifurcated trajectory of aged iCM reprogramming. Then, we screened 51 transcriptomic and epigenomic regulators of the barriers to aged-iCM reprogramming and found that Nuclear receptor subfamily 4 group A member 3 (Nr4a3), an pro-inflammatory transcription factor, induced cellular senescence to inhibit direct reprogramming during aging. Mechanistically, knockdown of Nr4a3 enhanced direct cardiac reprogramming by promoting cardiac gene programs and inhibiting fibrosis pathway and secretes SASP. In addition, knockdown of Nr4a3 promoted human reprogramming in primary ventricular human cardiac fibroblasts (HCFs) and improved heart function after MI.

Project description:Signal-induced proliferation-associated gene 1 (Sipa1) is known as a specific Rap1 GTPase-activating protein that negatively regulates Rap1 signaling. Although Sipa1 has been extensively studied in cancer research, its role in the wound healing response after myocardial infarction (MI) remains unexplored. To investigate the role of endogenous Sipa1 in MI, we performed permanent left anterior descending artery ligation in both Sipa1 knockout mice and their control littermates. Bone marrow transplantation, flow cytometry, cell sorting, and transcriptomic analysis were conducted to identify the cellular source of Sipa1 in the infarcted heart. The role of cardiac fibroblast-derived Sipa1 during MI was examined using Sipa1 deletion approaches, specifically in cardiac fibroblasts, in vivo and in vitro. Mice deficient in Sipa1 exhibited improved post-MI survival and cardiac function, along with attenuated expression of inflammatory mediators and diminished accumulation of Ly6Chigh monocytes and CCR2+ macrophages in the infarcted heart. Although Sipa1 was broadly expressed in the heart, cardiac fibroblasts were responsible for the Sipa1-induced deleterious phenotype as demonstrated by cardiac fibroblast-specific Sipa1 conditional knockout mice, which averted excessive inflammation and adverse cardiac remodeling following MI. Mechanistically, Sipa1 promotes the production of CCL2, CCL7 and granulocyte/macrophage colony-stimulating factor in the cardiac fibroblasts early after MI via a non-canonical RasGRP2-Ras-JNK signaling pathway, irrespective of canonical Rap1, thereby facilitating the accumulation and activation of inflammatory monocytes and macrophages. These results identify a previously unknown fibroblast-immune axis characterized by Sipa1, which initiates excessive inflammation and leads to poor outcomes after MI. Targeting Sipa1 offers a potential novel therapeutic strategy to optimize post-MI wound healing response, thereby preventing the development of chronic ischemic heart failure.

Project description:Myocardial infarction (MI) triggers a reparative response involving fibroblast proliferation and differentiation driving extracellular matrix modulation necessary to form a stabilizing scar. Recently, it was shown that a genetic variant of the base excision repair enzyme endonuclease VIII-like 3 (NEIL3) was associated with increased risk of MI in humans. Here, we report elevated myocardial NEIL3 expression in heart failure patients and marked myocardial upregulation of Neil3 following MI in mice, especially in a fibroblast-enriched cell fraction. Neil3-/-mice showed increased mortality after MI compared to WT, caused by myocardial rupture. Epigenomic analysis suggested dysregulated myofibroblast proliferation and differentiation in Neil3-/-hearts and several differentially expressed genes were downstream targets of differentially methylated/hydroxymethylated transcriptional regulators. Furthermore, proliferation of Vimentin+ and SMA+ (myo)fibroblasts was increased in Neil3 -/-hearts following MI. We propose that NEIL3-dependent modulation of epigenetic DNA methylation regulates cardiac fibroblast proliferation and thereby controls extracellular matrix modulation after MI.

Project description:Heart failure (HF) is a leading cause of morbidity and mortality. As adult cardiomyocytes (CMs) have little regenerative capacity, after myocardial infarction (MI), resident cardiac fibroblasts (CFs) synthesize extracellular matrix to form scar tissues, resulting in myocardial remodeling and HF. Thus, both cardiac regeneration and fibrosis are therapeutic targets for chronic MI. We previously reported that fibroblasts were directly reprogrammed into induced CMs (iCMs) by overexpression of cardiogenic transcription factors in acute and chronic MI. Here we show that in vivo cardiac reprogramming improved cardiac function, and reversed cardiac remodeling in chronic MI using a novel transgenic mouse system. Transcriptome analysis revealed that in vivo cardiac reprogramming suppressed signs of fibrosis and inflammation. Thus, in vivo cardiac reprogramming may be a promising approach for chronic HF.

Project description:Heart failure (HF) is a leading cause of morbidity and mortality. As adult cardiomyocytes (CMs) have little regenerative capacity, after myocardial infarction (MI), resident cardiac fibroblasts (CFs) synthesize extracellular matrix to form scar tissues, resulting in myocardial remodeling and HF. Thus, both cardiac regeneration and fibrosis are therapeutic targets for chronic MI. We previously reported that fibroblasts were directly reprogrammed into induced CMs (iCMs) by overexpression of cardiogenic transcription factors in vitro and in vivo in acute MI. Here we show that in vivo cardiac reprogramming generated iCMs from resident CFs, improved cardiac function, and reversed fibrosis in chronic MI using a novel transgenic mouse system. Transcriptome analysis revealed that in vivo cardiac reprogramming altered the interstitial cell landscape, suppressed signs of fibrosis and inflammation, and activated the angiogenic program. Thus, in vivo cardiac reprogramming may be a promising approach for chronic HF.